EP0990836A1 - Carbon dioxide snow container, and process and apparatus for making a carbon dioxide snow container - Google Patents

Abstract

The container consists of a shell (1) to contain the carbon dioxide in its solid state, one or more outlets to allow CO2 gas to escape spontaneously, and at least one inlet (3) connected to a source of liquid CO2. The inlet operates in one direction only, and the outlets are in the form of perforations or pores. The container is filled by connecting the liquid CO2 source to its inlet, allowing solid carbon dioxide snow to form inside it, and evacuating any CO2 gas.

Description

The invention relates to a snow container. carbon dioxide in the form of an envelope at least partially filled with dry ice, as well as a method and installation for manufacturing a container dry ice.

It is known that frozen or frozen, especially food to be kept at low temperature (around -20 ° C or less) without rupture of their cold chain since their freezing or freezing them until use, require warehouses, means of transport, and stores, equipped refrigeration facilities, which are currently generally electrical; however, in many case, for example for a non-motorized transport, it is impossible to transport products without removing them from the refrigeration system where they are stored, and the risks of a notable rise in temperature are important if weather conditions are unfavorable; in order to avoid such a rise in temperature during transport for example following of their sale "in quantity", it is usual to arrange frozen or deep-frozen products in a ice environment, ice being provided to the purchaser of the products by the supplier, generally as a courtesy. A certain ignorance of cold techniques on the part of suppliers and customers and the fact that the freezing power of ice is known to be relatively weak, leads them the more often to voluntarily overestimate, as a precaution, the amount of ice needed, and this results in significant unnecessary expense for the supplier. We might try to replace the ice with a product relatively inexpensive and with better cooling power, but it turns out that the outright replacement of ice with such products can be dangerous due to the very low temperature at which these products should be used (approximately -80 ° C for dry ice) and thus the risk of skin lesions that would cause their use without further precautions.

The object of the invention is to remedy these disadvantages and create a product in the form of a dry ice container with an envelope and a dose of dry ice arranged inside this envelope which is inexpensive as a result in particular the simplicity of its process and its installation of manufacturing, and the ability to automate this process and this installation in the immediate vicinity of the usage site.

To this end, the invention relates to a container for dry ice characterized in that it comprises a envelope and, in this envelope, carbon dioxide part of which is in solid state and another part is in the gaseous state, and in that the envelope presents at the minus one passage for spontaneous dioxide escape carbon in the gaseous state.

• l'enveloppe présente au moins un passage pour l'insertion d'un dispositif d'introduction du dioxyde de carbone, adapté pour assurer le transfert de dioxyde de carbone contenu dans une source de dioxyde de carbone, dans l'enveloppe ;
• le passage d'insertion du dispositif d'introduction est unidirectionnel ;
• le passage pour l'échappement spontané de dioxyde de carbone à l'état gazeux constitue également le passage pour l'insertion d'un dispositif d'introduction du dioxyde de carbone ;
• l'enveloppe présente plusieurs passages constitués par des perforations, pour l'échappement spontané de dioxyde de carbone à l'état gazeux ;
• l'enveloppe est en matériau poreux, ce matériau présentant des pores constituant des passages pour l'échappement spontané de dioxyde de carbone à l'état gazeux.

The container may also have one or more of the following characteristics:

• the envelope has at least one passage for the insertion of a device for introducing carbon dioxide, adapted to ensure the transfer of carbon dioxide contained in a source of carbon dioxide, into the envelope;
• the insertion passage of the introduction device is unidirectional;
• the passage for spontaneous escape of carbon dioxide in the gaseous state also constitutes the passage for the insertion of a device for introducing carbon dioxide;
• the envelope has several passages formed by perforations, for the spontaneous escape of carbon dioxide in the gaseous state;
• the envelope is made of porous material, this material having pores constituting passages for the spontaneous escape of carbon dioxide in the gaseous state.

The invention also relates to a method of manufacture of a dry ice container comprising an envelope, and, in this envelope, carbon, part of which is in solid state, characterized in that we house an envelope delimiting a space interior in a housing in which one maintains the envelope, facing an introducer carbon dioxide in the liquid state connected to a source of pressurized carbon dioxide in the state liquid, the envelope and the device are brought together introduction by setting in motion at least one of them then we continue the movement until that at least one end region of the device of introduction either in the interior space of the envelope, the through feeder the envelope in a passage of it, we interrupt the moving closer, we transfer through the device for introducing carbon dioxide in the state liquid from the source to the interior space where we do partially turn carbon dioxide into a liquid state in the form of a powdery solid and partly in the state gaseous, and as we fill the space inside by the pulverulent solid, the phase is evacuated gas, then the transfer of carbon dioxide is interrupted carbon in the liquid state, we remove the end region of the device for introducing the interior space, move the envelope and the introducer away, and the envelope containing carbon dioxide is evacuated to the solid state constituting the snow container carbon dioxide and the gas phase is allowed to escape excess by at least one pass of the envelope.

• pour poursuivre le mouvement jusqu'à ce qu'au moins une région d'extrémité du dispositif d'introduction soit dans l'espace intérieur de l'enveloppe, on insère le dispositif d'introduction dans un passage de l'enveloppe ;
• pour poursuivre le mouvement jusqu'à ce qu'au moins une région d'extrémité du dispositif d'introduction soit dans l'espace intérieur de l'enveloppe, on incise l'enveloppe au moyen du dispositif d'introduction pour créer un passage dans l'enveloppe et on insère le dispositif d'introduction dans ce passage.

The method can also include one or more of the following characteristics:

• to continue the movement until at least one end region of the introducer is in the interior space of the envelope, the introducer is inserted into a passage of the envelope;
• to continue the movement until at least one end region of the introducer is in the interior space of the envelope, the envelope is incised using the introducer to create a passage in the envelope and the introducer is inserted into this passage.

The invention also relates to an installation for manufacture of a dry ice container comprising an envelope, and, in this envelope, carbon, part of which is in solid state, characterized in that it includes a device for introducing carbon dioxide in the liquid state in the envelope, and this introduction device comprises a tubular body in which a channel extends, a head carried by the body to cross a passage of the envelope, and holes adapted to communicate the channel with inside the envelope when the head is at least partially in the envelope.

• le dispositif d'introduction comporte un outil d'incision pour inciser l'enveloppe en vue d'y réaliser un passage traversant, et un canal d'évacuation de dioxyde de carbone gazeux ;
• l'installation comporte un caisson dont une paroi porte le dispositif d'introduction, et un tiroir mobile entre une position ouverte d'amenée de l'enveloppe en vue de son remplissage et une position fermée de remplissage de l'enveloppe dans laquelle au moins une partie de la tête du dispositif d'introduction est à l'intérieur de l'enveloppe ;
• l'installation comporte un volet adapté pour former fond pour un tiroir coulissant, et lui-même coulissant indépendamment du tiroir ;
• l'installation comporte un puits d'évacuation des conteneurs, dont une partie supérieure est obturée ou dégagée sélectivement par un volet pivotant ;
• l'installation comporte une trémie d'alimentation en enveloppes, et le tiroir porte un capot solidarisé au dos de celui-ci et présentant une paroi sensiblement horizontale et s'étendant au niveau du haut du tiroir, adaptée pour obturer la base de la trémie sauf lorsque le tiroir est en position ouverte ;
• le dispositif d'introduction de dioxyde de carbone est relié à une source de dioxyde de carbone par l'intermédiaire d'une électrovanne, le dioxyde de carbone gazeux résiduel de l'installation en est évacué par l'intermédiaire d'un extracteur, et les conteneurs sont transmis à un bac depuis un puits d'évacuation par l'intermédiaire d'un appareil de comptage.

The installation can also include one or more of the following characteristics:

• the introduction device comprises an incision tool for incising the envelope in order to make a through passage therein, and a channel for evacuating carbon dioxide gas;
• the installation comprises a box, one wall of which carries the insertion device, and a movable drawer between an open position for supplying the envelope for filling and a closed position for filling the envelope in which at least a part of the head of the introducer is inside the envelope;
• the installation comprises a flap adapted to form the bottom for a sliding drawer, and itself sliding independently of the drawer;
• the installation comprises a container discharge well, an upper part of which is closed or selectively released by a pivoting flap;
• the installation comprises a hopper for supplying envelopes, and the drawer carries a cover secured to the back of the latter and having a substantially horizontal wall and extending at the top of the drawer, suitable for closing the base of the hopper except when the drawer is in the open position;
• the carbon dioxide introduction device is connected to a source of carbon dioxide via a solenoid valve, the residual carbon dioxide gas from the installation is removed therefrom via an extractor, and the containers are sent to a bin from an evacuation well via a counting device.

• la figure 1 est une vue schématique en perspective d'une première forme de réalisation d'un conteneur selon l'invention ;
• la figure 2 est une vue schématique en perspective d'une deuxième forme de réalisation d'un conteneur selon l'invention ;
• la figure 3 est une vue de dessus montrant schématiquement une phase de la fabrication d'un conteneur selon la figure 1 (phase de conditionnement de la neige carbonique dans une enveloppe) ;
• la figure 4 est une vue schématique en perspective d'un appareil entrant dans la constitution d'une installation selon l'invention, pour une enveloppe selon la forme de réalisation de la figure 1, dans une position de réception de l'enveloppe ;
• la figure 5 est une vue schématique en perspective d'un appareil entrant dans la constitution d'une installation selon l'invention, pour une enveloppe selon la forme de réalisation de la figure 2, dans une position de réception de l'enveloppe ;
• la figure 6 est une vue schématique en perspective des appareils des figures 5 et 6 dans une position de conditionnement de neige carbonique dans l'enveloppe ;
• la figure 7 est une section longitudinale schématique d'une canule de conditionnement appartenant à une installation selon l'invention, dans une première forme de réalisation ;
• la figure 8 est une section longitudinale schématique d'une canule de conditionnement appartenant à une installation selon l'invention, dans une deuxième forme de réalisation ;
• la figure 9 est une section longitudinale d'une canule de conditionnement appartenant à une installation selon l'invention, dans une troisième forme de réalisation ;
• les figures 10A à 10E montrent schématiquement des phases successives de la fabrication d'un conteneur selon l'invention et plus précisément du conditionnement de neige carbonique dans une enveloppe pour un conteneur selon une troisième forme de réalisation ; et
• la figure 11 est un schéma synoptique d'une installation selon l'invention.

Other characteristics and advantages of the invention will appear on reading the following description of forms and embodiments of the invention given by way of nonlimiting examples, illustrated by the accompanying drawings in which:

• Figure 1 is a schematic perspective view of a first embodiment of a container according to the invention;
• Figure 2 is a schematic perspective view of a second embodiment of a container according to the invention;
• Figure 3 is a top view schematically showing a phase of the manufacture of a container according to Figure 1 (conditioning phase of dry ice in an envelope);
• Figure 4 is a schematic perspective view of an apparatus forming part of an installation according to the invention, for an envelope according to the embodiment of Figure 1, in a position for receiving the envelope;
• Figure 5 is a schematic perspective view of an apparatus forming part of an installation according to the invention, for an envelope according to the embodiment of Figure 2, in a position for receiving the envelope;
• Figure 6 is a schematic perspective view of the apparatus of Figures 5 and 6 in a packaging position of dry ice in the envelope;
• Figure 7 is a schematic longitudinal section of a packaging cannula belonging to an installation according to the invention, in a first embodiment;
• Figure 8 is a schematic longitudinal section of a packaging cannula belonging to an installation according to the invention, in a second embodiment;
• FIG. 9 is a longitudinal section of a conditioning cannula belonging to an installation according to the invention, in a third embodiment;
• FIGS. 10A to 10E schematically show successive phases of the manufacture of a container according to the invention and more specifically of the packaging of dry ice in an envelope for a container according to a third embodiment; and
• Figure 11 is a block diagram of an installation according to the invention.

The product according to the invention intended to replace ice as a refrigerant to accompany for example in their transport of products which must temporarily be removed from an installation of refrigeration, is a container of dry ice.

This container has an envelope 1 and, in this envelope, carbon dioxide, part of which is in the solid state, and more precisely in the form of dry ice, and another part is in the state gaseous. As the container is intended to be used in ambient environment, dry ice sublimes in envelope, and it is necessary to allow the dioxide carbon in the gaseous state formed from escaping, for lack of what the pressure in the envelope would increase to cause it to burst; in order to allow spontaneous release of gaseous carbon dioxide superfluous, the envelope has one or more passages exhaust.

Also, the envelope must contain at least a passage for the insertion of a device introduction of carbon dioxide, which device introduction ensures the transfer of dioxide of carbon in a source of carbon dioxide to which it is connected, in the envelope; this same passage can in some cases be used for exhaust gas, as we will see below.

The source of carbon dioxide is for example a bottle of pressurized carbon dioxide at the liquid state; when liquid carbon dioxide under pressure released by means of a solenoid valve and transferred by means of the introducer penetrates in the envelope, it relaxes under pressure atmospheric, which creates a solid in powder form known as snow carbon dioxide, at a temperature well below 0 ° C, around -80 ° C, and carbon dioxide in the state gaseous. More specifically, consulting the diagram of Mollier shows that a given amount of dioxide liquid carbon under a pressure of 20 bars then transforms 53% into gas and 47% solid.

Insofar as we make sure to leave escape the gas phase here thanks to the passage (s) exhaust it is possible to completely fill the dry ice envelope, and the pressure under which builds up carbon dioxide initially pulverulent in the envelope produces a compaction of the mass of powder, which takes a very consistent state, without however reach the state of ice (which corresponds to a pressure of the order of at least 200 bars).

It is possible to design the envelope 1 under various shapes, and if it's made of flexible material, it on the one hand, it must be sufficiently resistant to withstand the pressure of carbon when filling, and on the other hand sufficiently thermally insulating to avoid any risk of cold burns during manipulations; these two properties can be obtained by choosing a sufficiently thick material important; in case the container is intended for use in the food sector, moreover, the material chosen must of course be suitable for this use (paper, cardboard, polyethylene).

In one embodiment, the envelope 1 is made of filter or porous paper whose air permeability is between 200 and 400 l / m ² / s. The passages for the spontaneous escape of carbon dioxide in the gaseous state are then the pores of the paper constituting the envelope, while the carbon dioxide snow is retained in the envelope. In this embodiment, advantageously, the casing initially has a single through hole, and to this is secured a one-way valve 11, for example with flaps arranged so as to close the through hole unless a device is inserted therein. introduction of carbon dioxide as will be described below.

Geometrically, this envelope can present various forms, for example a form approximately prismatic with triangular section (Figure 1) with an attached flat base 12 made of cardboard in which the through hole extends and which is provided valve 11, the base having two parallel edges in protruding or slightly peeled off facilitating its implementation place in slides (Figures 3 and 4), as a vacuum cleaner bag, or a form parallelepiped (figure 2) or spherical (figures 10A to 10E) facilitating its installation in a shaped frame corresponding, for its filling. Alternatively, the through hole and its one-way valve can be replaced by a simple pre-cut 13 made up by one incision or by two cross incisions in one of the sides of the envelope 1. In both cases, the envelope 1 may not be porous, but the passages for spontaneous release of carbon dioxide to the gaseous state are formed by perforations 14 made therein before or during filling; these perforations can for example be circular and have a diameter of the order of 4mm (Figure 2).

In another embodiment, the envelope, which can be geometrically of the same shape that previously, is not initially equipped with a valve or a pre-cut for the insertion of the carbon dioxide introducer but the passage for this device is created by a tool which is provided with the device itself, which is forcibly inserted into the envelope (whose mechanical characteristics are appropriately chosen), as will be seen in the after.

The exhaust of carbon dioxide gas at the as the envelope is filled can also be ensured not by pores or perforations thereof but by means specially provided for this purpose in the device introduction, as will also be seen in the following, the exhaust after filling then being ensured through the passage where the device was previously inserted introduction of carbon dioxide. This feature is particularly well suited to the embodiment in which the device introduction of carbon dioxide creates its own passage, because preferably the envelope does not then present no pores or perforations allowing escape significant gaseous carbon dioxide so not to compromise its rigidity during its piercing. The filling of envelopes including Figures 1 and 2 can be carried out in a filling 2 such as that of FIGS. 4 to 6, one of which back wall here approximately vertical carries the device 3 for introducing carbon dioxide, and which is adapted to receive a sliding drawer 21 to which is associated a frame 22 of suitable shape so that the envelopes 1 can be immobilized there.

More specifically, the drawer 21 is movable between an open position in which we introduce a envelope for filling and then evacuated the envelope filled with dry ice constituting the dry ice container (Figures 4 and 5 corresponding respectively to the envelopes of Figures 1 and 2), and a closed position in which one fills the envelope (Figure 6). To this end, the system introduction 3 is in the form of a cane or a cannula extending approximately perpendicular to the rear wall of the box 2 and one end of which has injection holes inside the box, and the sliding movement of drawer 21 is a rectilinear translational movement back and forth in the direction in which the introduction device 3. A flap 23 approximately horizontal forming the bottom is mounted itself sliding in the same direction as the drawer 21, regardless of it. Like, in the position open the drawer, insert the envelope, frame 22 is above a drainage well for containers (not shown in Figures 4 to 6), the bottom 23 is then placed under the frame 22 in order to support the envelope and prevent it from falling into the drainage well; when the drawer is operated towards the closed position, the bottom 23 is pushed by the face front of the drawer inside the box; at the end of closing movement, envelope 1 comes into contact of the introducer 3 and the movement is continuing, the head of it enters the envelope by crossing the valve or the precut thereof, or again by creating its own passage, according to the form of realization, liquid carbon dioxide is introduced in the envelope, forming carbon dioxide snow and gas and then the arrival of carbon dioxide is interrupted; then the drawer is brought back to the open position while the bottom 23 remains at inside the cabinet, and so when the drawer is in the fully open position, the snow container carbon dioxide falls by gravity into the evacuation well. In the embodiments of Figures 4 to 6, the chassis 22 has a parallelepiped shape.

In the embodiment of Figures 3 and 4, the drawer 21 has a rear wall approximately vertical near which also extend vertically two bars forming a slide 24, the base is fixed to the base of the chassis 22.

So an envelope like the one in the Figure 1, which was arranged above the frame 22 when the drawer 21 is in the open position such so that its added base 12 is in alignment with the space between the slides 24 and the rear wall of the drawer, can be vertically housed in the chassis being by its base applied against or at immediate proximity of this rear wall; in this embodiment, the rear wall of the drawer is pierced with a through hole opposite that of envelope 1 to allow the passage of the device introduction 3.

In the embodiment of Figure 5, the chassis 21 has approximately the same shape as the envelope of Figure 2 that it should house, with barely larger, and it's not necessary that the drawer 21 has a rear wall.

The device 3 for introducing dioxide Figure 7 carbon is a cannula intended for introduce liquid carbon dioxide into a flap or pre-cut envelope; this cannula has a body over almost its entire length tubular 31 of generally cylindrical shape, one of which end (not shown) is intended to be connected to the source of carbon dioxide through a conduit passing by a control solenoid valve, the other of which end carries a head 32 connected to the body by a throat; the end of the body 31 carrying the head 32 has 33 calibrated through holes through around the throat, and distributed at least approximately regularly around it (for example four holes distributed at 90 °); holes 33 have to communicate the inside of the cannula, that is to say a longitudinal channel 34, with the outside, to introduce carbon dioxide into the envelope when the head and part of the body of the cannula are at inside of it. The head has one end free rounded, for example in a spherical cap or hemispherical to gently push the valve 11 or the edges of the pre-cut 13 of the envelope during the approach of the envelope contained in the drawer 21. This cannula is intended for filling envelopes including carbon dioxide discharge passages gaseous are pores or perforations made at this end.

The device 3 of FIG. 8 comprises also a hollow body 31, but this body leads to the opposite of its end intended to be connected to the source of carbon dioxide, a 32 head smaller diameter and elongated which extends in alignment with the body 31 and which itself has a channel 35 aligned coaxially with channel 34 of the body and connecting to him ; the head also has an end here rounded, possibly hemispherical; however, in this embodiment, it is not the body 31 which has holes for introducing carbon dioxide, but the elongated head 32 is provided near its distal end of a few holes (e.g. four through holes 33 calibrated approximately distributed regularly.

As this embodiment is intended for be used with envelopes without perforation appropriately performed beforehand, in order to create its own passage in the envelope, it is equipped with a incision tool 36 which can be interchangeable; this incision tool 36 is made in the form of a blade hollow inside which the head is housed elongated 32 except in its area of connection to the body 31; as it is also intended to be used with envelopes without pores or exhaust perforations, it is surrounded, except near its end distal, through an annular channel 37. The blade 36 is tapered on the one hand towards and beyond the end distal of the head 31 so as to present a cutting free end, and on the other hand, in section transverse, on either side of the head 31, that is to say going forward and going back of the section plane of FIG. 8, so as to present two side cutting edges. The blade 36 is pierced with holes 38 opposite the holes 33 of the head to allow the passage of liquid carbon dioxide towards the envelope; it is also pierced with holes 39 making communicate channel 37 with the outside, since being intended for be used with an envelope without notable pores or carbon dioxide gas exhaust holes she must allow to escape from the envelope the surplus of it; thanks to this structure, during its translation, the envelope is pierced by the end tapered from blade 36 and incised by the cutting edges side of it, and the translational movement of the envelope is interrupted when a significant part (by example two-thirds) of the blade length 36 is inside the envelope; so the dioxide liquid carbon is transmitted to device 3 and can flow into the envelope through the holes 33 of the head and 38 of the blade; excess carbon dioxide gas crosses those of the holes 39 of the blade in communication with the annular channel 37 which are inside of the envelope, travels through the annular channel 37 in the direction from the body 31, and escapes to the outside by those of the blade holes 39 which are outside of the envelope.

The introducer 3 in the form of Figure 9 realization is intended to be used here with envelopes having rounded shapes, for example spherical example, to improve positioning relative of the envelope and the cannula. This form of realization presents approximately the same structure as that of Figure 8; however, it has plus a stop 36 'intended to be applied against the envelope and limiting the penetration of the head elongated 31 surrounded by the blade 37 in the envelope 1 to the desired location. This 36 'stopper has a shape corresponding to that of the envelope, here in a cap spherical; in this embodiment, the blade 36 does not extend towards the body 31 between the stop 36 'and the body, and it suffices that the stop has an annular light 39 'around the head 31 and that the space between the stopper and the body is not completely enclosed at the periphery so that the carbon gas entering the annular channel 37 by the holes 39 could escape outside through the annular light 39 '; in the embodiment of Figure 9, the stop 36 'is carried by tabs 31' welded to the body 31 and forming around the head 32 a squirrel cage by the spaces of which the dioxide carbon gas can escape; in order to facilitate the fixing the pins 31 ′, the body 31 shown in the Figure 9 has a larger diameter than that of the figure 8.

We can note that thanks to the fact that we leave escape the excess carbon dioxide (at -78.5 ° C), we ensures carbon dioxide subcooling liquid and a yield of transformation into snow carbon dioxide higher than 47%.

Figures 10A to 10E relate more particularly a spherical container whose envelope 1 is made of polyethylene and has a diameter for example about ten centimeters, the part of the installation manufacturing this container which is shown being a variant close to what has been described previously. This installation part allows you to partially house the envelopes 1 in a box 2, one wall of which carries a device 3 for introducing carbon dioxide, by means of a drawer 21, to pierce these envelopes, introduce carbon dioxide, and evacuate containers made of the envelope containing dry ice; the box and the drawer have a general hemispherical shape whose dimensions interiors are suitable for housing with little play the spherical envelopes 1 and are both movable in translation. On the back of the drawer 21 is here secured a cover having a substantially horizontal wall 24 extending at the top of the drawer 21, playing a role valve as we will see below.

A hopper 4 for feeding envelopes 1 is arranged with its base slightly above the level of the wall 24, at a location such that the wall 24 closes off the base of the hopper except when the drawer 21 is in a fully open position shown in the figure 10E. An evacuation well 5 disposed between the box 2 and the balance of the hopper 4, leads to its part above the level of the base of the box 2 and of the drawer 21; this upper part of the evacuation well 5 is selectively closed or released by a flap 23 forming bottom which here is not sliding like previously (Figures 4 to 6) but pivoting around a horizontal axis so that it can be retracted into the well to pass through the containers during their evacuation; the lower part of the well 5 opens into a tank 6 where dry ice containers can be removed for example manually.

The sequence of operations is as follows: a spherical envelope 1 being half housed in the drawer 21, the drawer is brought together by sliding the box 2 inside which the device projects introduction 3 here preferably as described in reference to FIG. 9, the flap 23 being in its closing position of well 5 (FIG. 10A); during at the end of the approximation run, envelope 1 is incised by the device 3, and when the drawer 21 is applied against box 2, the introduction of dioxide liquid carbon is ordered; as soon as he enters the envelope, the liquid expands forming snow carbon dioxide and carbon dioxide whose excess can escape as was mentioned with reference to the Figure 9; all the while the base of the hopper is closed by the wall 24; when the envelope is practically full (Figure 10B), the drawer 21 is brought back from its closed position to its open position. Then the box 2 is itself brought back by sliding in direction of drawer 21 (FIG. 10C) until the dry ice container (envelope filled with carbon dioxide) reaches above flap 23 swivel. Then, the flap or bottom 23 is controlled for retract into well 5, or the weight of the container causes the bottom 23 to retract, and the container enters well 5 (Figure 10D) to reach tray 6. One more retraction of drawer 21 brings the wall 24 to a location where it no longer closes the base of the hopper 4, and another casing 1 escapes from the hopper and comes to stand in front of the drawer 21 (Figure 10E), and another cycle can begin.

Figure 11 shows the main elements of the entire automatic installation according to the invention can be used in self-service at by means of a “coin mechanism”. This figure 11 shows the box 2 into which the device opens introduction 3 of carbon dioxide linked to a source 7 of liquid carbon dioxide such as a bottle of liquid carbon dioxide at a pressure of 20 bars, per through a solenoid valve 8 activated in connection with a timer (not shown). Drawer 21 sliding is surmounted by the hopper 4, and, the well outlet 5 opens at its upper part under the drawer 21 and at its lower part in a tray 6. A extractor for example with propeller 9 connected to the drawer 21 which must be relatively waterproof to constitute a space almost confined, is planned to discharge outside at carbon dioxide to an outlet the gaseous state contained in the drawer following the filling. Means (not shown) can be designed to heat certain elements of the box 2 and / or of the drawer 21 and / or of the insertion device 3 (especially the head of it) to avoid formation water or dry ice.

A tester 10 is inserted in the well 5 or between well 5 and tank 6 to count the containers delivered, display the result (s) of the counting (for example display by means of a first display a daily result and by means of a second display a total result), and possibly weigh the containers to verify the operation of the installation.

A remote monitoring device 11 makes it possible to check the storage level of the envelopes, the counting, operating an alarm, and detecting installation malfunctions.

Hopper 4 can be designed to contain a few dozen envelopes and receive an item adaptable allowing to triple or quadruple the capacity; it includes a detector and a filling (not shown) to alert the operator of the installation when the number of envelopes drops to ten.

The container manufacturing process implemented during the operation of this installation is as follows:
Following the introduction of a suitable token or coin, the drawer 21 is brought into a position allowing the introduction into the latter of an envelope by a simple flow by gravity from the hopper 4 The envelope is transferred to the device 3 for introducing liquid carbon dioxide which optionally pierces it, unless this operation has been carried out beforehand in the installation itself by an interchangeable tool or outside it. ci, then lets the carbon dioxide flow after activation of the solenoid valve 8, for a duration predetermined by the timer. At the end of the predetermined period, the drawer is retracted and the container formed is evacuated by a simple flow by gravity into the well 5, and from there into the tank 6 after a control phase during its passage at the level of the control device 10. The container being in the tray 6 can then be removed. The time which elapses between the introduction of the token or the coin and the arrival of the dry ice container in the bin is only a few seconds, for example approximately 7 seconds.

In the event that the installation is intended to the public, the operation is discontinuous and allows between ten and fifteen start-ups per hour for example a dozen hours per day.

The installation can also be installed in workshop, in a version designed for operation continuous for example seven hours a day, or two seven-hour periods separated by one hour rest ; in this case the flow of containers may be extended by a chute to a receptacle in height (of the order of one meter for example).

Claims (16)

Dry ice container characterized in that it includes an envelope (1) and, in this envelope, carbon dioxide, part of which is the solid state and another part is in the gaseous state, and in that the envelope has at least one passage (14) for spontaneous escape of carbon dioxide at the gaseous state. Container according to claim 1, characterized in that the envelope (1) has at least one passage for the insertion of a device for introducing the carbon dioxide, suitable for transferring carbon dioxide from a source (7) of carbon dioxide of carbon, in the envelope (1). Container according to claim 2, characterized in that the device insertion passage introduction is unidirectional. Container according to claim 2 or 3, characterized in that the passage for the exhaust spontaneous gaseous carbon dioxide constitutes also the passage for the insertion of a device carbon dioxide introduction. Container according to any one of Claims 1 to 4, characterized in that the envelope (1) has several passages consisting of perforations (14), for spontaneous escape of dioxide carbon in the gaseous state. Container according to any one of Claims 1 to 5, characterized in that the envelope (1) is made of porous material, this material having pores constituting passages for the exhaust spontaneous carbon dioxide gas. Method of making a snow container carbonic with an envelope (1), and, in this envelope, carbon dioxide, part of which is the solid state, characterized in that one houses a envelope (1) delimiting an interior space in a housing in which the envelope is maintained, opposite a device (3) for introducing dioxide carbon in the liquid state connected to a source (7) of carbon dioxide under pressure in the liquid state, brings the envelope and the introducer closer together setting at least one of them in motion and then continue movement until at least one region end of the introducer either in the interior space of the envelope, the device introduction (3) passing through the envelope (1) in a passage of it, we interrupt the movement of approximation, we transfer through the device of introduction of carbon dioxide in the liquid state of the source (7) to the interior space where the carbon dioxide in liquid state partly in state of powdery solid and partly in the gaseous state, and as we fill the interior space with the powdery solid, the gaseous phase is removed, then the transfer of carbon dioxide in the state is interrupted liquid, remove the end region of the device of introduction of the interior space, we move away the envelope and the introducer, and evacuated the envelope containing carbon dioxide in the state solid constituting the dry ice container and we allows excess gas to escape by at least a passage (14) of the envelope. Method according to claim 7, characterized in that to continue the movement until at minus one end region of the introducer (3) either in the interior space of the envelope (1), inserts the introducer into a passage the envelope. Method according to claim 7, characterized in that to continue the movement until at minus one end region of the introducer (3) either in the interior space of the envelope (1), cut the envelope using the introducer to create a passage in the envelope and we insert the introduction device in this passage. Container manufacturing facility dry ice with an envelope (1), and, in this envelope, carbon dioxide, part of which is in the solid state, characterized in that it comprises a device (3) for introducing carbon dioxide to the liquid state in the envelope, and this device introduction comprises a tubular body (31) in which extends a channel (34), a head (32) carried by the body to cross a passage of the envelope, and holes (33) adapted to communicate the channel with inside the envelope when the head is at least partially in the envelope. Installation according to claim 10, characterized in that the introduction device (3) has an incision tool (36) for incising the envelope (1) in order to make a passage there through, and a channel (37) for evacuating carbon dioxide carbon gas. Installation according to claim 10, characterized in that it comprises a box (2) of which a wall carries the introducer (3), and a drawer (21) movable between an open position for supplying the envelope (1) for filling and a position closed filling of the envelope in which at at least part of the head (32) of the device introduction (3) is inside the envelope. Installation according to claim 10, characterized in that it comprises a suitable flap (3) to form the bottom for a sliding drawer (21), and itself sliding independently of the drawer. Installation according to claim 10, characterized in that it comprises a well (5) container disposal, including an upper part is selectively closed or released by a flap (23) swivel. Installation according to claim 12, characterized in that it includes a hopper (4) envelope feeder (1), and the drawer (21) carries a cover secured to the back thereof and having a wall (24) substantially horizontal and extending at level of the top of the drawer (21), suitable for closing the hopper base except when the drawer (21) is in open position. Installation according to claim 12, characterized in that the introducer (3) carbon dioxide is connected to a source (7) of carbon dioxide through a solenoid valve (8), the residual carbon dioxide gas from the installation is evacuated via a extractor (9), and the containers are sent to a bin (6) from an evacuation well (5) via a counting device (10).

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